Deconvolution of complex NMR spectra in small molecules by multi frequency homonuclear decoupling (MDEC)

Ana Paula D M Espindola; Ronald Crouch; John R. DeBergh; Joseph M. Ready; John B. MacMillan

doi:10.1021/ja907110e

Deconvolution of complex NMR spectra in small molecules by multi frequency homonuclear decoupling (MDEC)

Ana Paula D M Espindola, Ronald Crouch, John R. DeBergh, Joseph M. Ready, John B. MacMillan

Research output: Contribution to journal › Article › peer-review

28 Scopus citations

Abstract

(Graph Presented) A new technique to deconvolute complex 1H NMR spectra of small molecules has been developed that utilizes shape selective pulses to simultaneously decouple multiple protons. A limitation in the assignment of the relative configuration of small molecules is the ability to accurately obtain coupling constants. Other methods such as the E.COSY and the 2D J-resolved are available to obtain complicated coupling constants; the multiple homonuclear decoupling method (MDEC) described is a rapid and simple technique. Three examples of increasing spectral complexity, menthol, cholesteryl acetate and a C₁₆ fatty acid, demonstrate the utility of the technique. Increasing the experimental utility, the single pulse MDEC experiment can be incorporated in other 1D experiments, such as a 1D-TOCSY to solve specific problems.

Original language	English (US)
Pages (from-to)	15994-15995
Number of pages	2
Journal	Journal of the American Chemical Society
Volume	131
Issue number	44
DOIs	https://doi.org/10.1021/ja907110e
State	Published - Nov 27 2009

ASJC Scopus subject areas

Catalysis
Chemistry(all)
Biochemistry
Colloid and Surface Chemistry

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10.1021/ja907110e

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abstract = "(Graph Presented) A new technique to deconvolute complex 1H NMR spectra of small molecules has been developed that utilizes shape selective pulses to simultaneously decouple multiple protons. A limitation in the assignment of the relative configuration of small molecules is the ability to accurately obtain coupling constants. Other methods such as the E.COSY and the 2D J-resolved are available to obtain complicated coupling constants; the multiple homonuclear decoupling method (MDEC) described is a rapid and simple technique. Three examples of increasing spectral complexity, menthol, cholesteryl acetate and a C16 fatty acid, demonstrate the utility of the technique. Increasing the experimental utility, the single pulse MDEC experiment can be incorporated in other 1D experiments, such as a 1D-TOCSY to solve specific problems.",

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T1 - Deconvolution of complex NMR spectra in small molecules by multi frequency homonuclear decoupling (MDEC)

AU - Espindola, Ana Paula D M

AU - Crouch, Ronald

AU - DeBergh, John R.

AU - Ready, Joseph M.

AU - MacMillan, John B.

PY - 2009/11/27

Y1 - 2009/11/27

N2 - (Graph Presented) A new technique to deconvolute complex 1H NMR spectra of small molecules has been developed that utilizes shape selective pulses to simultaneously decouple multiple protons. A limitation in the assignment of the relative configuration of small molecules is the ability to accurately obtain coupling constants. Other methods such as the E.COSY and the 2D J-resolved are available to obtain complicated coupling constants; the multiple homonuclear decoupling method (MDEC) described is a rapid and simple technique. Three examples of increasing spectral complexity, menthol, cholesteryl acetate and a C16 fatty acid, demonstrate the utility of the technique. Increasing the experimental utility, the single pulse MDEC experiment can be incorporated in other 1D experiments, such as a 1D-TOCSY to solve specific problems.

AB - (Graph Presented) A new technique to deconvolute complex 1H NMR spectra of small molecules has been developed that utilizes shape selective pulses to simultaneously decouple multiple protons. A limitation in the assignment of the relative configuration of small molecules is the ability to accurately obtain coupling constants. Other methods such as the E.COSY and the 2D J-resolved are available to obtain complicated coupling constants; the multiple homonuclear decoupling method (MDEC) described is a rapid and simple technique. Three examples of increasing spectral complexity, menthol, cholesteryl acetate and a C16 fatty acid, demonstrate the utility of the technique. Increasing the experimental utility, the single pulse MDEC experiment can be incorporated in other 1D experiments, such as a 1D-TOCSY to solve specific problems.

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Deconvolution of complex NMR spectra in small molecules by multi frequency homonuclear decoupling (MDEC)

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